JPH06101199B2 - Disk device - Google Patents

Description

Description: TECHNICAL FIELD OF THE INVENTION The present invention relates to a disc device such as an optical disc device for recording or reproducing information on an optical disc.

[Technical Background of the Invention] In recent years, a large amount of image information of a document or the like is photoelectrically converted by two-dimensional optical scanning, and this photoelectrically converted image information is recorded in an image recording device, or if necessary. 2. Description of the Related Art Recently, an optical disk has been used as an image recording device in an image information file device that can be searched and reproduced, and can be reproduced and output as a hard copy or a soft copy.

Conventionally, in such an optical disc apparatus, an optical disc for recording information in a spiral shape is used, and information is recorded or reproduced by an optical head which is linearly moved by a linear motor in the radial direction of the optical disc. ing.

By the way, in such an optical disc apparatus, in order to stabilize recording and reproduction and shorten the access time, a constant rotation number method (CAV method; Co
nstant Angular Velocity method) is used for recording and playback. In the case of this CAV method, the recording or reproducing timing, that is, the frequency of demodulation and modulation is constant.

Also, because of the high density recording of the optical disc, the rotation speed of the optical disc is slowed down as it moves from the inner side to the outer side of the optical disc, that is, a constant linear velocity method (CLV method; Constant) when the optical disk is seen from the optical head. Linear Ve
The locity method) is used for recording and playback. Although this CLV type optical disc has an advantage that the recording capacity per disc is large, it has a drawback that the access time is long because the rotation speed of the rotary motor needs to be changed. Therefore, as a method of performing recording / reproduction by rotating the optical disc at a constant speed and changing the recording or reproduction timing, that is, the frequency of demodulation and modulation according to the access position, the (M-CAV method; Modulate Constant Angu
lar Velocity method) has been put to practical use.

[Problems of Background Art] However, in the above optical disk device, CAV
There are devices that handle optical discs of the M.CAV system and devices that handle optical discs of the M-CAV system, and there is no device that can handle optical discs of both systems. Therefore, it is desired that the optical discs of both types can be handled.

[Object of the Invention] The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a disc device capable of handling both a CAV type disc and an M-CAV type disc. is there.

[Summary of the Invention] In order to achieve the above object, the present invention relates to a disk device for reproducing data at an access position of a disk having spiral or concentric tracks based on a reproduction processing frequency. The access position to be supplied by the supply means, and the output means outputs the reproduction processing frequency of predetermined data regardless of the access position supplied by the supply means of the disc, or by the supply means of the disc. Depending on the supplied access position, it outputs the reproduction processing frequency of the data that has been changed stepwise with a constant reproduction processing frequency as a reference, and when the disk is set in the device, the set disk, Regardless of the access position supplied by the above-mentioned supply means, data is reproduced at a constant reproduction processing frequency. Is it the first type of disc on which data is played?
And identification information indicating whether the disc is a second type disc in which data is reproduced at the reproduction processing frequency which is increased stepwise according to the access position supplied by the supply unit, by the output unit. Based on the predetermined reproduction processing frequency output, the reading means reads the set disc, and when the disc is set in the device, the position where the identification information of the disc is stored is set by the supplying means. The disc, which is supplied as an access position, causes the output means to output a predetermined reproduction processing frequency to the reading means, and after the reading means reads the identification information, the disc set by the reading means is the first disc. When the disc is read as a one-system disc, the output unit outputs a constant reproduction processing frequency, and the reading unit When it is read that the set disc is the disc of the second method, the output unit is read from a certain reproduction processing frequency according to the access position to be accessed supplied by the supply unit. Data is reproduced by outputting the reproduction processing frequency that is changed stepwise and higher.

That is, by controlling the reproduction processing frequency to be constant or changed according to the identification information read from the disc to reproduce the data from the disc, the CAV, MC
This makes it possible to handle both AV-type discs.

[Embodiment of the Invention] An embodiment of the present invention will be described below with reference to the drawings.

FIG. 1 shows a schematic structure of a disk device such as an optical disk device of the present invention. That is, the optical disk (disk) 1 has a spiral or concentric circular information storage unit with a constant radial pitch, and is rotationally driven by the motor 4. The motor 4 is composed of a spindle motor whose rotation is controlled at a constant speed (600 rpm) by a rotation motor control circuit 10 described later. As shown in FIG. 2, the optical disc 1 has a donut-shaped metal coating layer such as tellurium or bismuth coated on the surface of a circular substrate made of glass or plastics. A notch, that is, a reference position mark ₁₁ is provided in the vicinity of the center of the.

Further, on the optical disc 1 is the reference position marks 1 ₁ "0"
Is divided into 256 sectors of "0 to 255". The optical disc 1 includes a CAV system (constant processing frequency for modulation and demodulation) (first system disc), and M-CAV.
There are two types (a second type disc) of a system (modulation and demodulation processing frequency change), and the M-CAV type optical disc 1 has a constant recording density on the entire surface, that is, inside or outside, and a CAV type optical disc. In No. 1, the recording density becomes coarser from the inside to the outside. Further, in the (same) predetermined position (identification information recording area) of the inner portion of the optical disk 1 used in the CAV method or CLV method, the frequency of modulation and demodulation is constant regardless of the access position, or the frequency of modulation and demodulation is fixed. Identification information indicating whether or not the frequency of is changed according to the access position is recorded. The predetermined position is a position where the reference signals for modulation and demodulation in the CAV type and M-CAV type optical disc 1 have the same frequency and the same recording density. As the identification information, for example, CAV
In the case of the system, the code "00" is recorded and M-CAV
In the case of the method, the code "01" is recorded.

Variable length information (image information) is recorded over a plurality of blocks on the M-CAV type optical disc 1. The number of sectors in one block of the M-CAV type optical disc 1 is, for example, 40 sectors inside and 20 sectors outside. Further, the number of sectors in one block in the CAV type optical disc 1 is constant, for example, 40 sectors.
A block header A including a block number and a track number is recorded at the start position of the block, for example, when the optical disc 1 is manufactured. If each block in the M-CAV type optical disc 1 does not end at the sector switching position, a block gap is provided so that each block always starts from the sector switching position.

An optical head 5 for recording and reproducing information is provided on the back side of the optical disc 1. The optical head 5 is fixed to a movable portion 6 of a DC linear motor 3 composed of a movable portion 6 and a fixed portion 8, and the movement of the movable portion 6 linearly moves in the radial direction of the optical disc 1, that is, in the a and b directions in the figure. Be moved to. Reference numeral 9 is a detector for detecting the position of the movable portion 6, and these two kinds of phases differ according to the moving amount of the movable portion 6, that is, the optical head 5 by a so-called overlapping lattice type detection method (this phase relation is Output a detection signal (depending on the direction). On the other hand, the optical head 5 fixed to the linear motor 3 includes a semiconductor laser, a collimator lens, a beam splitter, an objective lens, a focus drive coil for driving the objective lens in the optical disc 1 direction, and an objective lens in the radial direction of the optical disc 1. Tracking drive coil, a focusing detector having a pair of photodetectors for detecting whether or not the laser beam light is focused on the optical disc 1, and a tracking having a pair of photodetectors for detecting whether or not tracking is performed on an information track. It consists of a detector. A detection signal is output from each photodetector to a corresponding processing circuit, and a predetermined voltage is applied to each drive coil and semiconductor laser from each drive circuit.

The control circuit 20 controls the entire device according to a signal from an external device, that is, a host computer (not shown). The linear motor drive circuit 14 drives the linear motor 3 according to the target position signal supplied from the control circuit 20 and the output signal of the detector 9.

On the other hand, the rotary motor drive circuit 10 determines the speed according to the rotation clock from the motor 4 and controls the speed to the speed set by the control circuit 20. The focus servo circuit 11 adjusts the focus of the objective lens in the optical head 5 in accordance with the detection signal from the detector in the optical head 5, and the focus pull-in circuit 16 does not operate focusing. Focusing is performed accurately when changing to a working state. The tracking servo circuit 12 moves the objective lens in the radial direction of the optical disc 1 so that the light beam emitted through the objective lens in the optical head 5 is at the center of the track in response to the detection signal from the detector in the optical head 5. It is something that can be moved. Also, the tracking servo circuit
12 temporarily stops the servo operation and emits a track jump drive pulse according to the track jump pulse from the track jump pulse generation circuit 17 to move the objective lens,
The beam light can be moved by one track.

In addition, the pit signal waveform shaping circuit 13 is used for the optical head 5 described above.
The detection signal from the detector inside is also subjected to waveform shaping.
The binarization circuit 18 binarizes the waveform shaping signal from the pit signal waveform shaping circuit 13.

The reference clock generator 41 generates a reference clock. The variable clock generation circuit 19 uses the reference clock supplied from the reference clock generator 41 as the control circuit 20.
A clock signal (reference signal) having a frequency (time width) according to the clock speed information supplied from is generated. That is, the frequency of the clock signal becomes higher (the time width is shorter) as the position of the optical head 5 moves toward the outside of the optical disc 1.

In addition, the reproduction synchronous clock extraction circuit 23 is
When the control signal is supplied from the variable clock generating circuit 19, it is recorded at the beginning of the block header A of each block from the data supplied from the binarizing circuit 18 according to the clock signal supplied from the variable clock generating circuit 19. This is to extract the reproduction synchronization clock that is being used. The demodulation circuit 22 performs MFM demodulation of the data supplied from the binarization circuit 18 following the reproduction synchronization clock from the reproduction synchronization clock extraction circuit 23 according to the clock signal from the variable clock generation circuit 19. is there. The serial-parallel conversion circuit 25 converts the reproduction signal supplied from the demodulation circuit 22 from serial data to parallel data according to the clock signal from the variable clock generation circuit 19.

The header discriminating circuit 26 discriminates only the header data from the reproduced signal supplied from the demodulating circuit 22 according to the clock signal from the variable clock generating circuit 19.
The recording / reproducing header register 29 stores the accessed header data supplied from the control circuit 20. The header comparator 28 includes the recording / reproducing header register 29.
The header data stored in the header discriminating circuit 26 is compared with the header data supplied from the header discriminating circuit 26, and a coincidence signal is output when they coincide.

The parallel-serial conversion circuit 24 converts a reproduction signal supplied from a recording / reproduction switching circuit 27, which will be described later, from parallel data to serial data according to the clock signal from the variable clock generation circuit 19. The modulation circuit 21 includes the parallel-serial conversion circuit 24 described above.
The MFM modulation of the data supplied from the MFM is performed according to the clock signal from the variable clock generating circuit 19. The laser drive circuit 15 records data by driving and controlling a semiconductor laser (not shown) in the optical head 5 in accordance with the modulation signal supplied from the modulation circuit 21.

The recording / reproduction switching circuit 27 outputs the reproduction data following the header data to the recording / reproduction data buffer 30 when the coincidence signal is supplied from the header comparator 28 in response to the reproduction control signal from the control circuit 20. It is a thing.
Further, the recording / reproducing switching circuit 27 outputs recording data following the header data supplied from the recording / reproducing data buffer 30 to the parallel / serial conversion circuit 24 in response to a recording control signal from the control circuit 20. It is a thing.

The recording / reproducing data buffer 30 stores the reproducing data from the recording / reproducing switching circuit 27 and the recording data from the recording / reproducing data transfer circuit 32. Also, the reproduction data (identification information) of the recording / reproduction data buffer 30 when determining the disk mode at the time of startup.
Are output to the control circuit 20. The error correction code addition / error correction circuit 31 adds an error correction code to the recording data stored in the recording / reproducing data buffer 30 and performs error correction on the reproducing data stored in the recording / reproducing data buffer 30. Is. The recording / reproducing data transfer circuit 32 includes the recording / reproducing data buffer 30.
Playback data supplied from the external interface circuit
The recording data is transferred to the host computer (not shown) via 33, and the recording data supplied from the host computer via the external interface circuit 33 is output to the recording / reproducing data buffer 30.

As shown in FIG. 3, the ROM 42 serving as a storage circuit includes clock speed information of the optical disc 1 for each 256 tracks, the number of sectors in one block at this clock speed, and the first block in the 256 tracks at the above speed. No. and the start sector of the block correspond to each other and store a conversion table.

When the control circuit 20 determines the disc mode at the time of start-up, the optical disc 1 set in the apparatus is a CAV disc according to the reproduction data (identification information) supplied from the recording / reproduction data buffer 30. It is determined whether the disc is an M-CAV type disc or not. For example, when the code "00" is supplied as the identification information, it is determined that the CAV optical disk 1 is set, and when the code "01" is supplied as the identification information, the M-CAV optical disk 1 is selected. It is determined that it has been set. Further, the control circuit 20 changes the clock signal output from the variable clock generation circuit 19 according to the determination result to a constant first mode regardless of the access position, and changes the clock signal according to the access position. One of the second modes is selected.

That is, in the case of the CAV method, the first mode is selected,
In the case of the M-CAV system, the second mode is selected. For example, when the first mode is selected, as shown by the broken line in FIG. 4, a clock signal having a constant frequency is output regardless of the access position of the optical disk 1, and when the second mode is selected. As shown by the solid line in the figure, a clock signal having a frequency changed according to the access position of the optical disc 1 is output. In this case, the frequencies of the clock signals for the blocks having the same number of sectors are the same, and the frequency changes are stepwise.

Further, when the block number of the recording or reproducing position, that is, the position to be accessed, supplied from the host computer through the external interface circuit 33, the control circuit 20 receives the block number in the first mode. The access position corresponding to the number is read from the ROM 42, and access is performed by the linear motor 3 and the optical head 5 with the frequency of the clock signal kept constant. In the case of the second mode, the clock speed corresponding to the block number. The information and the access position are read from the ROM 42, and the linear motor 3 and the optical head 5 perform the access while the clock signal corresponding to the clock speed is output. Since the clock speed information and the reading (calculation) of the access position are described in detail in Japanese Patent Application No. 59-32825, they are omitted here.

The variable clock generation circuit 19 includes a frequency divider 72, a phase comparator 43, a phase / voltage conversion circuit, as shown in FIG.
PL consisting of 44, voltage controlled oscillator circuit 45, and frequency divider 46
It is composed of an L circuit 48. As a result, the control circuit 20 controls the frequency division number of the frequency divider 46 to control the output of the PLL circuit 48, that is, the frequency of the clock signal.

Next, the operation in such a configuration will be described. First, the optical disc 1 is set in this device. Then, the control circuit 20 first drives the motor 4 to rotate the optical disc 1 at a constant speed. Then, the control circuit 20 reads the clock speed information and the access position, that is, the track number and the start sector number according to the block number corresponding to the identification information recording area from the ROM 42. As a result, the control circuit 20 outputs the clock speed information to the variable clock generation circuit 19. Then, the variable clock generation circuit 19 uses the reference clock from the reference clock generator 41 to generate a frequency (time width) according to the clock speed information supplied from the control circuit 20.
To generate a clock signal, a modulation circuit 21, a demodulation circuit 22, a reproduction synchronous clock extraction circuit 23, a parallel-serial conversion circuit 24, a serial-parallel conversion circuit 25, a header discrimination circuit
Supply to 26.

Further, by the track number, the control circuit 20 converts the track number into a scale value, and drives the linear motor driver 14 until the scale value and the position detected by the output of the position detector 9 match. , Move the optical head 5. Then, when the movement of the optical head 5 is completed, the detection signal from the detector in the optical head 5 is waveform-shaped by the waveform shaping circuit 13 and is binarized by the binarization circuit 18.
Quantized demodulation circuit 22 and recovered sync clock extraction circuit 23
Is supplied to. Then, the reproduction synchronous clock extraction circuit 23
Extracts the reproduction synchronization clock recorded first in the block header A from the supplied data and outputs it to the demodulation circuit 22.

As a result, the demodulation circuit 22 performs MFM demodulation of the reproduction synchronization clock and the read signal subsequently supplied from the binarization circuit 18, and outputs it to the recording / reproduction switching circuit 27 via the serial-parallel conversion circuit 25. At the same time, it is supplied to the header discrimination circuit 26. Then, the header discriminating circuit 26 discriminates only the header data and outputs it to the control circuit 20 and the header comparator 28. As a result, the control circuit 20 determines the track to which the optical head 5 corresponds from the header data, and compares this track with the target track. As a result of this comparison, if the control circuit 20 is separated by several tens of tracks or more, the linear motor 3 moves the optical head 5 again,
When the number of tracks is 10 tracks or less, the optical head 5 is moved by the number of corresponding tracks by the track shamp.

When the optical head 5 corresponds to the target track,
The header discrimination circuit 26 discriminates only the header data and outputs it to the header comparator 28. At this time, the header data of the block corresponding to the target, that is, the identification information recording area is stored in advance in the header register 29 by the control circuit 20,
The header data of this header register 29 is the header comparator 28.
Is being supplied to. Thereby, the header comparator 28 outputs a coincidence signal to the recording / reproducing switching circuit 27 when the header data coincide with each other. Then, the recording / reproduction switching circuit 27 outputs the reproduction data supplied following the header data to the recording / reproduction data buffer 30.

The reproduction data of the recording / reproduction data buffer 30 is supplied to the control circuit 20 after being error-corrected by the error correction code addition / error correction circuit 31. As a result, the control circuit 20
If the supplied reproduction data (identification information) is "00", it judges that the CAV optical disc 1 has been set, and selects the first mode. Therefore, as shown by the broken line in FIG. 4, regardless of the access position of the optical disc 1,
Clock signal of constant frequency is variable clock generator 19
The control circuit 20 is controlled to the state of being output from.

When the supplied reproduction data (identification information) is "01", the control circuit 20 determines that the M-CAV type optical disc 1 is set, and selects the second mode. Therefore, as indicated by the solid line in the figure, the control circuit 20 is controlled so that the variable clock generating circuit 19 outputs the clock signal having the frequency changed according to the access position of the optical disc 1.

Recording is performed (accessed) from the host computer (not shown) via the external interface circuit 33 in the state where the first mode is selected as described above.
It is assumed that the block number is supplied to the control circuit 20. Then, the control circuit 20 uses the conversion table of the ROM 42 to calculate the track and start sector of the target block. Further, since the control circuit 20 selects the first mode, the variable clock generation circuit 19 causes the clock signal of a constant frequency to be output regardless of the access position. As a result, the clock signal having the constant frequency is supplied to the conversion circuit 21, the demodulation circuit 22, the reproduction synchronous clock extraction circuit 23, the parallel-serial conversion circuit 24, the serial-parallel conversion circuit 25, and the header discrimination circuit 26.

Further, the control circuit 20 operates in the same manner as when accessing the above-mentioned identification information recording area by the track number, and makes the beam light of the optical head 5 correspond to the track of the target block.

At this time, the recording data is transferred from the host computer to the external interface circuit 33 and the recording / reproducing data transfer circuit 32.
The data is stored in the recording / reproducing data buffer 30 via, and a correction code is added.

When the match signal of the block header of the target block is supplied from the header comparator 28 to the recording / reproducing switching circuit 27, the recording / reproducing switching circuit 27 converts the recording data of the recording / reproducing data buffer 30 into a parallel-serial conversion circuit 24. Is supplied to. The recording data converted into serial data by the parallel-serial conversion circuit 24 is subjected to MFM modulation by the modulation circuit 21 and supplied to the laser drive circuit 15. As a result, the laser drive circuit 15 drives the semiconductor laser (not shown) in the optical head 5 according to the supplied modulation signal to record data.

Also, when data is recorded in another block, the same operation as described above can be performed. In this case, data is recorded with the frequency of the clock signal being constant even if the block position is changed.

It is also assumed that a block number for reproduction (access) is supplied from the host computer (not shown) to the control circuit 20 via the external interface circuit 33. Then, similarly to the case of the above recording, the beam light of the optical head 5 is made to correspond to the track of the target block.

When the match signal of the block header of the target block is supplied from the header comparator 28 to the recording / reproducing switching circuit 27, the reproducing data from the serial-parallel conversion circuit 25 is recorded by the recording / reproducing switching circuit 27 into the recording / reproducing data buffer. Supplied to 30. The reproduction data stored in the recording / reproduction data buffer 30 is error-corrected by the error correction code addition / error correction circuit 31 and transferred to the host computer via the recording / reproduction data transfer circuit 33 and the external interface circuit 33. .

Further, when reproducing data of other blocks, the same operation as described above can be performed. In this case, data is reproduced with the frequency of the clock signal being constant even if the block position is changed.

Next, in the state where the second mode is selected as described above, it is assumed that the block number for recording (accessing) is supplied to the control circuit 20 from the host computer (not shown) via the external interface circuit 33. . Then, the control circuit 20 uses the conversion table of the ROM 42 to calculate the track, start sector, and clock speed information of the target block. Then, the control circuit 20 outputs the clock speed information to the variable clock generation circuit 19. Then, the variable clock generation circuit 19 changes the reference clock generator 41.
A clock signal having a frequency corresponding to the clock speed information supplied from the control circuit 20 is generated using the reference clock from the modulation circuit 21, the demodulation circuit 22, the reproduction synchronous clock extraction circuit 23, and the parallel-serial conversion circuit 24. , Serial-parallel conversion circuit 25 and header discrimination circuit 26.

Further, the control circuit 20 operates in the same manner as when accessing the above-mentioned identification information recording area by the track number, and makes the beam light of the optical head 5 correspond to the track of the target block.

At this time, the recording data is transferred from the host computer to the external interface circuit 33 and the recording / reproducing data transfer circuit 32.
Are stored in the recording / reproducing data buffer 30 via the.

When the match signal of the block header of the target block is supplied from the header comparator 28 to the recording / reproducing switching circuit 27, the recording / reproducing switching circuit 27 converts the recording data of the recording / reproducing data buffer 30 into a parallel-serial conversion circuit 24. Is supplied to. The recording data converted into serial data by the parallel-serial conversion circuit 24 is subjected to MFM modulation by the modulation circuit 21 and supplied to the laser drive circuit 15. As a result, the laser drive circuit 15 drives the semiconductor laser (not shown) in the optical head 5 according to the supplied modulation signal to record data.

Also, when data is recorded in another block, the same operation as described above can be performed. In this case, data is recorded with the frequency of the clock signal being increased as the block position is located on the outer peripheral side.

It is also assumed that a block number for reproduction (access) is supplied from the host computer (not shown) to the control circuit 20 via the external interface circuit 33. Then, as in the case of the above recording, the clock speed information corresponding to the block is read, and the clock signal having the frequency corresponding to the clock speed information is supplied to the modulation circuit 21 and the demodulation circuit.
22, the reproduction synchronous clock extraction circuit 23, the parallel-serial conversion circuit 24, the serial-parallel conversion circuit 25, and the header discrimination circuit 26.

Further, as in the case of the above recording, the laser beam of the optical head 5 is made to correspond to the track of the target block.

When the match signal of the block header of the target block is supplied from the header comparator 28 to the recording / reproducing switching circuit 27, the reproducing data from the serial-parallel conversion circuit 25 is recorded by the recording / reproducing switching circuit 27 into the recording / reproducing data buffer. Supplied to 30. The reproduction data stored in the recording / reproduction data buffer 30 is error-corrected by the error correction code addition / error correction circuit 31 and transferred to the host computer via the recording / reproduction data transfer circuit 33 and the external interface circuit 33. .

Further, when reproducing data of other blocks, the same operation as described above can be performed. In this case, as the block position is located on the outer peripheral side, the data is reproduced with the frequency of the clock signal increased.

As described above, when the optical disk is set and started (at the time of initial setting), the clock signal of a predetermined frequency is modulated by the modulation means,
The identification information which is output to the demodulating means and which indicates whether the frequency of the clock signal recorded in the predetermined position of the set optical disc, that is, the identification information recording area is constant or changed is read. Accordingly, the frequency of the clock signal is fixed or changed to a frequency according to the access position of the optical disc for recording and reproduction, so that both the CAV type optical disc and the M-CAV type optical disc can be handled. .

Since the identification information storage area may be an area having the same recording density, if the area having the same recording density,
The rotation speed of the rotary motor may be different between the first mode and the second mode. In this case, the conventional constant linear velocity method (CLV method) can also be used.

[Effects of the Invention] As described above, according to the present invention, it is possible to provide a disk device capable of handling both a CAV system disk and an M-CAV system disk.

[Brief description of drawings]

The drawings show one embodiment of the present invention. FIG. 1 is a diagram schematically showing the overall configuration, FIG. 2 is a diagram showing the configuration of an optical disc, and FIG. 3 is a diagram showing an example of storage of a conversion table. , 4th
FIG. 5 is a diagram for explaining the relationship between the position of the optical disc and the frequency of the clock signal, and FIG. 5 is a block diagram for explaining the configuration of the variable clock generation circuit. 1 ... Optical disc (disk), 3 ... Linear motor,
4 ... Motor, 5 ... Optical head, 15 ... Laser drive circuit, 19 ... Variable clock generation circuit, 20 ... Control circuit, 21
...... Modulation circuit, 22 ・ ・ ・ Demodulation circuit, 23 ・ ・ ・ Reproduction synchronization clock extraction circuit, 24 ・ ・ ・ Parallel-serial conversion circuit, 25 ・ ・ ・
… Serial-parallel conversion circuit, 27 …… Recording / playback switching circuit, 30 …… Recording / playback data buffer, 41 …… Reference clock generator, 42 …… ROM.

Claims (1)

[Claims] 1. A disk device for reproducing data at an access position of a disk having a spiral or concentric circular track based on a reproduction processing frequency, and supplying means for supplying an access position of the disk to be accessed. The reproduction processing frequency of predetermined data is output regardless of the access position supplied by the supply means of the disc, or a fixed reproduction processing frequency is set as a reference according to the access position supplied by the supply means of the disc. As the output means for outputting the reproduction processing frequency of the data which has been stepwisely changed as, and when setting the disk to the device, the set disk, regardless of the access position supplied by the supply means, Is the disc of the 1st system, in which data is reproduced at a constant reproduction processing frequency? And identification information indicating whether reproduction of the data in stepwise increasing altered the reproduction processing frequency in accordance with the access position to be supplied is a disk of a second scheme implemented by the supply means,
Based on the predetermined reproduction processing frequency output by the output unit, a reading unit that reads from the set disc, and a position where the identification information of the disc is stored when the disc is set in the device. It is supplied as an access position from the supply means, causes the output means to output a predetermined reproduction processing frequency to the reading means, and after the reading means reads the identification information, it is set by the reading means. When the disc is read as the first type disc, the output means
When a certain reproduction processing frequency is output and the disc set by the reading unit is read as the disc of the second system, the output unit is accessed by the supply unit. A disk device comprising: control means for outputting the reproduction processing frequency which is stepwise increased from a constant reproduction processing frequency according to an access position to reproduce the data.